Reconstruction of enhancer–target networks in 935 samples of human primary cells, tissues and cell lines

Cao, Qin; Anyansi, Christine; Hu, Xihao; Xu, Liangliang; Xiong, Lei; Tang, WM; Mok, Myth T.S.; Cheng, Chao; Fan, Xiaodan; Gerstein, Mark; Cheng, Alfred S.L.; Yip, Kevin Y.

doi:10.1038/ng.3950

Cited by 205 publications

(306 citation statements)

References 57 publications

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“…However, these approaches lose the tissue specificity of the interactions. Other approaches integrate many diverse chromatin signals such as posttranslational histone modifications, chromatin accessibility, or transcriptional activity [57][58][59][60][61][62], and combine them with sequence features [63], or evolutionary constrains [64]. While these methods predict enhancer-gene association with good performance, they require for each specific condition of interest a multiplicity of input datasets, which are often not available.…”

Section: Discussionmentioning

confidence: 99%

Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs

Ibn-Salem

Andrade‐Navarro

2018

Preprint

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Section: Discussionmentioning

confidence: 99%

Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs

Ibn-Salem

Andrade‐Navarro

2018

Preprint

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“…The first uses 35 chromosomal conformation capture techniques to identify physical interaction between two loci in the genome [25][26][27][28][29][30] , but it is not clear which of these interactions are linked to a regulatory role. The second measures the correlation of transcription activity between noncoding sequences and nearby genes 31,32 , assuming the two are signatures of a coordinated regulatory function. Finally, single nucleotide variants (SNVs) can be associated to significant 40 differences in gene expression, thus qualifying as expression QTL (eQTL) that presumably reside within or close to enhancers 33 .…”

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confidence: 99%

Enhancer-gene maps in the human and zebrafish genomes using evolutionary linkage conservation

Clément

Torbey

Gilardi-Hebenstreit

et al. 2018

Preprint

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Gene regulation by enhancer sequences controls the spatiotemporal expression of target genes, often over long genomic distances. Current methods used to identify these interactions in the human genome require complex experimental setups and are restricted to specific cell types. Here we use PEGASUS, an approach that captures evolutionary signals 5 of synteny conservation to predict such interaction potentially in any biological context. We apply it to the human and zebrafish genomes and exploit the 1.3 million human and 55,000 zebrafish enhancers that we predicted to uncover fundamental principles of gene enhancer function in vertebrates. We show that the number of enhancers linked to a gene positively correlates with expression breadth in space and time and that the enhancer-target distance 10 is evolutionarily neutral. We uncover almost 2000 regulatory interactions ancestral to vertebrates, which are strongly enriched in core developmental processes. Using PEGASUS and its evolutionary view of enhancer-gene interactions, we provide a highly complementary resource to functional assays which uncovers key principles of enhancer biology.

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“…Using machine learning, Cao et al propose to integrate predicted REMs into cell-type specific interaction networks [6], similar to Hait et al, who also provide regulatory-maps derived from statistical associations between the activity of REMs and target gene-expression [21]. Shooshtari et al combined chromatin accessibility data with Genome-Wide Association study Studies (GWAS) to better pinpoint regulatory events in autoimmune and inflammatory diseases [47].…”

Section: Introductionmentioning

confidence: 99%

Integrative analysis of epigenetics data identifies gene-specific regulatory elements

Schmidt

Hebel

Wegner

et al. 2019

Preprint

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Understanding the complexity of transcriptional regulation is a major goal of computational biology. Because experimental linkage of regulatory sites to genes is challenging, computational methods considering epigenomics data have been proposed to create tissue-specific regulatory maps. However, we showed that these approaches are not well suited to account for the variations of the regulatory landscape between cell-types. To overcome these drawbacks, we developed a new method called StitchIt, that identifies and links putative regulatory sites to genes. Within StitchIt, we consider the chromatin accessibility signal of all samples jointly to identify regions exhibiting a signal variation related to the expression of a distinct gene. StitchIt outperforms previous approaches in various validation experiments and was used with a genome-wide CRISPR-Cas9 screen to prioritize novel doxorubicin-resistance genes and their associated non-coding regulatory regions. We believe that our work paves the way for a more refined understanding of transcriptional regulation at the gene-level.

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Reconstruction of enhancer–target networks in 935 samples of human primary cells, tissues and cell lines

Cited by 205 publications

References 57 publications

Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs

Computational Chromosome Conformation Capture by Correlation of ChIP-seq at CTCF motifs

Enhancer-gene maps in the human and zebrafish genomes using evolutionary linkage conservation

Integrative analysis of epigenetics data identifies gene-specific regulatory elements

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